DE10016484A1 - Cable, consists of at least two cable elements, each of which has two cores, and element chambers. - Google Patents

Abstract

A cable (1) consists of at least two cable elements (4), each of which has at least two cores (6). Each of the two cable elements is located in a chamber element (5) chamber. The chambers have a curved section.

Description

The invention relates to a cable with at least two cable elements and a method of manufacturing a cable, each of the cable elements element comprises at least two cores stranded together and each of the two cable elements each in a chamber of a chamber element is arranged.

Such cables are already known from US 5 789 711, according to this document each a cable element from two ver together roped veins in a chamber of a star-shaped chamber element is arranged. However, such a cable is relatively large Fluctuations in its properties.

It is an object of the invention to provide a cable which to meet future requirements.

As a solution, the invention proposes a cable in which at least one of the chambers continuously ge around the corresponding cable element has curved area. Such an arrangement enables one much better routing and storage of the corresponding cable element, so that the properties of the cable according to the invention we are considerably more constant over the cable length.  

The proposed chamber provides an opening towards the cable element area that does not necessarily enclose the cable element or have to change hands. Only a relatively small Be is enough rich, for example between 20 ° and 100 °, preferably about 90 °, to implement the leadership of the invention.

In the present context, the term "continuously ge curves "a line, the first derivative of which is continuous according to the location applies here in particular with regard to the cross section through a cable element.

The curvature preferably corresponds to the circumference of the strand gene cable element. The amount of stranding is from the cross-cut Shell surface, within which the stranded wires run, is formed.

The advantage of such a cable is a significant improvement in quality. Due to the resulting high-precision distances, application categories from classification groups 5 and 6 up to group 7 can be achieved.

In order to achieve sufficient precision of the cable, is pre suggest that the curvature of the continuously curved area is less than 10%, preferably less than 5%, of the curvature of the The circumference of the strand differs, with every known definition under curvature possibility of a curvature, in particular mathematically the first Ab line surface is understood.  

Another embodiment of the invention proposes that the continuously ge curved area has a circumferential radius that is not greater than 10 %, preferably not greater than 5%, of the stranding radius, where the stranding radius is understood to mean the radius of the stranding circumference. There can ensure a precise position of the cable elements and that Cables manufactured or prepared under high requirements be put.

In order to ensure that the inserted cable elements are routed well, it is proposed that the continuously curved area in cross section at least 20 °, preferably 45 °, in particular 90 "of the stranding cross encloses.

It is provided that at least two of the A of a cable element connected to each other via insulation are. This results in an even higher precision of the proposed Ka bels reached. This characteristic is also independent of the use a chamber element with a continuously curved area from before part.

Between the insulation of the two stranded wires, one can ver binding web can be provided. This can increase the capacity of the cable can be set. This results in a further manipulated variable which is used for Cable definition can be used.  

By fixing the wires over the bridge, for example in the case of conventional twisting of the veins points, which have irregular and deforming effects on a cable element can be avoided.

It is suggested that the insulation be made of full ethylene. There can lead to a particularly good insulation behavior of the stranded wires against each other. Instead of full ethylene, however also materials such as PP (polypropylene) or FEP (polyterafluoroethylene) be used.

It is also suggested that the insulation is foamed and preferably comprises foamed ethylene. This allows better Dielectric values (ε is smaller for foamed ethylene than for non-foamed ones foamed ethylene) optimized (minimized) the geometric conditions become.

For example, to decouple the cable according to the invention improve, it is proposed that the chamber element strike having. To reinforce the decoupling, the chamber element can also be used be enclosed in a laminated metal foil. In particular, can change the stroke direction along the path length. This applies to the Kabelele ment and / or the chamber element. This allows the manufacture of the Simplified and economically interesting. Dar In addition, quality improvements can also be made, for example  of electrical values such as NEXT, wave resistance and damping can be achieved.

To improve the decoupling of the signal-transmitting elements To achieve te, it is proposed that the chamber element is half includes conductive material. For example, materials such as PE (Polyethylene), VPE (cross-linked polyethylene), PU (polyurethane), PP (Po lypropylene), FEP (tetra-fluoromethylene / hexalfluoropropylene), PA (polya mid) or PBT (polybutylene terephthalate) with a high percentage of soot or other suitable additives can be enriched and used.

The manufacture of the chamber element can be especially for the materia designed tools and machine components.

In one embodiment, the cable element can be made thin-walled det and thus be very flexible. This allows it to swirl on without various conventional extruders can be manufactured.

In order to provide an inexpensive method for producing a Realizing the outer cable, it is proposed that before stranding of two cable elements one below the other and with one chamber element, at least one of the cable elements using an S-Z method from we at least two wires are stranded. It can be done via the conventional S-Z For example, process a duplex wire into the chamber profile without disadvantageous torsional action. In addition, you can a variety of elements covering souls, such as metallic  and non-metallic foil screens or fixings, vorese hen to affect the cable properties in the desired manner rivers.

The term S-Z stranding process describes a stranding process where the lay direction changes over the cable length. By the For example, S-Z stranding can be used work inline with a surface line. In addition, this S-Z Stranding additionally inline with a duplex core twist one Group winners or combined via S-Z-Twinner.

A method is also proposed that when two cable elements are stranded with one another and with a chamber element, at least one of the chamber elements is twisted by means of a reversed double impact. As a result, for example, a significant increase in performance or a reduction in the cost of producing a required cable quality in the UTP / (S) FTP area of category 6 can be achieved.

By using basic fiber optic elements, such as FO compact core, simplex and duplex FO cable, as well as FO Bundle and multi elements can implement hybrid cable constructions become.

In addition, to enable cost-effective production, it is proposed that the twisting of the two cable elements with each other  and with the chamber element by means of the aforementioned procedure ren is done.

It is understood that the cores include both solid cores and strands can sen.

The present invention is particularly suitable for data cables and he enables a surprising increase in quality, especially with data cables.

Other goals, advantages, and characteristics are described below Description of attached drawings shown. It shows:

Fig. 1 is a schematic sectional view of a cable according to the invention and

Fig. 2 is an enlarged sectional view of a cable element according to the invention.

The embodiment of a cable 1 according to the invention shown in FIG. 1 shows a chamber element 2 , which forms four chambers with an outer covering 3, not described in detail. A stranded duplex core 4 is arranged in each of the four chambers. Viewed in cross section of the cable element 2 , the chambers each have a continuous curvature corresponding to the stranding circumference of the duplex core 2 . The continuously curved area differs less than 5% from the respective area formed from the lateral surface, within which the four duplex wires 4 each run. The resulting high-precision spacing enables significant quality improvements for the cable. In addition, the radius of the continuously curved region is not greater than 5% of the radius of the Verseilumang of the duplex core 4 arranged therein.

The continuously curved area encloses approximately 90 ° of the stranding cross section of the duplex core 4 , which enables particularly good guidance.

The chamber element 2 has a metallic steel strand 5 in the center. This takes on the function of strain relief. Instead of the steel strand 5 , steel wire or any other metallic material can also be used.

It can be particularly advantageous to use a staku conductor cher the function as a strain relief element with shielding effect takes.

The strain relief can also be made of non-metallic materials such as for example, glass fiber bundles or aramid bundles are provided.

The metallic strand 5 can also consist of copper, for example, and act as a signal-transmitting element. For example, cable constructions with a core, a pair of cores, a triple or quad construction, etc. can be implemented.

Through the use of further signal-transmitting elements can also use cable constructions such as fiber optic cables Hybrid construction as a compact fiber optic core, duplex fiber optic core, Quadro fiber optic core or as a bundle fiber optic core.

The four duplex elements 4 and the chamber element 5 are stranded together by SZ methods. This enables the cable to be manufactured particularly economically.

FIG. 2 shows an enlarged representation of a duplex core. 4 The two wires 6 are stranded together and arranged within an insulation 7 . Both isolations 7 are connected to one another by a web 8 . The capacitance of the cable can be adjusted by the web dimension. In this exemplary embodiment, the insulation 7 consists of full ethylene.

Claims (15)

1. Cable ( 1 ) with at least two cable elements ( 4 ), each of the cable elements ( 4 ) comprising at least two wires ( 6 ) stranded together and each of the two cable elements ( 4 ) being arranged in a chamber of a chamber element ( 5 ), characterized in that at least one of the chambers one around the corresponding cable element. ( 4 ) has a continuously curved area. 2. Cable ( 1 ) according to claim 1, characterized in that the curvature of the continuously curved area deviates less than 10%, preferably less than 5%, from the curvature of the Verseilum beginning. 3. Cable ( 1 ) according to claim 2, characterized in that the ste curved portion has a circumferential radius which is not greater than 10%, preferably not greater than 5%, of the Verseilra diusses. 4. Cable ( 1 ) according to one of claims 1 to 3, characterized in that the continuously curved region 1111 cross section at least 20 °, preferably 450 in particular 90 ° of the cable cross section Ver. 5. Cable ( 1 ) according to one of claims 1 to 4, characterized in that at least two of the stranded wires ( 6 ) of a cable element ( 4 ) are connected to each other via insulation ( 7 ). 6. Cable ( 1 ) according to claim 5, characterized in that between the insulation's ( 7 ) of the two wires ( 6 ) connecting these the web ( 8 ) is provided. 7. Cable ( 1 ) according to claim 5 or 6, characterized in that the insulation ( 7 ) consists of full ethylene. 8. Cable ( 1 ) according to claim 5 or 6, characterized in that the insulation ( 7 ) comprises foamed, preferably foamed ethylene. 9. Cable ( 1 ) according to any one of the preceding claims, characterized in that the chamber element ( 2 ) has an impact. 10. Cable ( 1 ) according to any one of the preceding claims, characterized in that the direction of lay changes over the path length. 11. Cable ( 1 ) according to any one of the preceding claims, characterized in that the chamber element ( 2 ) is enclosed in a laminated metal foil. 12. Cable ( 1 ) according to any one of the preceding claims, characterized in that the chamber element ( 5 ) comprises a semiconducting material, preferably that the chamber element consists of a semiconducting material. 13. A method for producing a cable, preferably a cable ( 1 ) according to any one of claims 1 to 11, characterized in that before stranding two cable elements ( 4 ) with each other and with a chamber element ( 2 ) at least one of the cable elements ( 4th ) is stranded from at least two conductors ( 6 ) using an SZ method. 14. A method for producing a cable, preferably according to claim 12 or preferably for producing a cable according to one of claims 1 to 11, characterized in that by egg twisting two cable elements ( 4 ) with each other and with a chamber element ( 2nd ) at least one of the cable elements ( 4 ) is twisted by means of a reversed double lay. 15. The method according to claim 12 or 1, characterized in that the stranding of the two cable elements ( 4 ) with each other and with the chamber element ( 2 ) by means of an SZ method and / or by means of a reversed double lay.